Báo cáo lâm nghiệp: "End-use related physical and mechanical properties of selected fast-growing poplar hybrids (Populus trichocarpa × P. deltoides)" potx

To assess the basic technical quality of each clone, ten-sion wood and false heartwood proportion, density, dimenten-sional sta-bility, modulus of elasticity MOE and modulus of rupture M

Original article

End-use related physical and mechanical properties of selected

Department of Forest and Water Management, Laboratory of Wood Technology, Ghent University, Coupure Links 653, 9000 Ghent, Belgium

(Received 7 August 2006; accepted 18 January 2007)

Abstract – This study focused on physical and mechanical properties of fast-growing poplar clones in relation to potential end uses with high added

value A total of 14 trees from three different clones, all P trichocarpa × deltoides (T×D) hybrids, were felled in a poplar plantation in Lille (Belgium):

six ‘Beaupré’, four ‘Hazendans’ and four ‘Hoogvorst’ Growth rate was found to have no significant influence on the physical mechanical properties Although the investigated clones are genetically closely related, important variations in physical and mechanical properties were observed Specific features such as spatial distribution of tension wood and dimensional stability are the main quality factors It was concluded that ‘Beaupré’ is suitable for a wide range of high value added applications, such as plywood or construction wood ‘Hazendans’ and ‘Hoogvorst’ will need adapted technology

in processing Further research is needed to characterize clonally induced variation in properties and to assess adequate processing strategies for multiclonal poplar stands.

Populus trichocarpa × P deltoides / physical properties / mechanical properties / veneer / plywood

Résumé – Propriétés physiques et mécaniques d’hybrides de peupliers à croissance rapide en fonction de l’aptitude à l’emploi Cette étude porte

sur les caractéristiques physiques et mécaniques du bois de clones de peupliers à croissance rapide, en fonction de l’aptitude à l’emploi Quatorze arbres ont été étudiés, provenant d’une plantation de peuplier à Lille (Belgique), appartenant à trois hybrides différents de P trichocarpa × deltoides, à savoir

six “Beaupré”, quatre “Hazendans” et quatre “Hoogvorst” Les caractéristiques de croissance n’ont pas a ffecté de manière significative les propriétés physiques et mécaniques Bien que les clones étudiés soient génétiquement rapprochés, des variations importantes ont été constatées dans les propriétés physiques et mécaniques Des caractéristiques spécifiques telles que la distribution spatiale du bois de tension et la stabilité dimensionnelle du bois sont des propriétés importantes a ffectant sur la qualité du produit final On peut conclure que le bois de “Beaupré” est apte à la fabrication de panneaux contreplaqués et de bois de sciage Une adaptation de la technologie de transformation sera nécessaire pour les clones ‘Hazendans’ et ‘Hoogvorst’ Des recherches approfondies seront requises afin d’évaluer la variabilité induite par l’e ffet clonal ainsi que pour identifier des stratégies adaptées à la transformation du bois de peuplements multiclonaux.

Populus trichocarpa × P deltoides / bois de tension / bois de cœur / propriétés physico-mécanique / contreplaqué

1 INTRODUCTION

In spite of criticism against monocultures of poplar from

the ecological point of view, timber and biomass from poplar

plantations remain one of the most important resources for the

wood industry in various countries As a fast-growing species,

poplar enhances the possibility to cover increasing wood

de-mands

Since 1948, research performed at the former Institute for

Poplar Cultivation (currently the Institute for Nature and

For-est Research – INBO,Geraardsbergen, Belgium), has played a

leading role in selection and breeding of poplar, not only for

vigour, but also in terms of adaptation to climate conditions

as well as disease resistance Due to recent shifts in resistance

to rust disease and changing industrial demands, new selected

poplar hybrids had to be introduced This necessitates

contin-uous monitoring of wood quality with respect to possible

end-uses

* Corresponding author: Lieven.DeBoever@UGent.be

Wood quality is to a large extent genetically deter-mined [26] Moreover, wood is formed by a living individual with cyclic activity, resulting in an annually fluctuating growth

in width and height, which is dependent on site conditions and influenced by age Consequently, wood properties can show a certain variation between and within individuals of the same clone in poplar This may affect the overall wood quality and its final utilisation

The produced poplar wood is usually light, with a density between 360 and 540 kg/m3, and quite strong resulting in a high strength-density ratio The latter is an important feature with regard to construction purposes Modulus of elasticity to density ratios of 22 to 27 do position poplar between soft-woods (values around 30) and other hardwood species (values around 20) [12, 20, 21]

In poplar wood, the physical and mechanical properties tend to display clone-to-clone as well as inter- and intra-tree variations Density is commonly high at the bottom of the tree, decreases to a minimum at mid-height, then increases again near the top of the merchantable stem [3, 8, 18, 24] Density Article published by EDP Sciences and available at http://www.afs-journal.org or http://dx.doi.org/10.1051/forest:2007040

Table I Genetic background of investigated clones with dendrometrical characteristics for selected trees and total stand; mean radial increment

and radial increment of last 10 years (cm), circumference at BH (cm) and total tree height (m) with standard deviations

Mean radial increment last 10 years (cm) 1 02 ± 0.15 1 01 ± 0.14 1 42 ± 0.19

0.7 1.2 3.8 6.5 11.0 meter

Mechanical testing according to EN 408 (50x2x2 cm)

Disc A Heartwood Tension wood

Disc B Dimensional stability (50x50x50x mm)

North

Ea st

South West

Veneer log

Figure 1 Partitioning of the trees in relation to the different specimens required for testing

variations between clones have been described by different

authors Peszlen [18] could not find a significant difference

among 10 to 15-year-old clones of P deltoides × nigra, while

Hernández et al [10] examined 9-year-old P deltoides ×

ni-gra and found a significant clone-to-clone variation Earlier

comparison of fast-growing Belgian poplar clones proved that

major variations exist [21,22] Beaudoin et al [3] and

Hernán-dez et al [10] pointed out significant but weak negative

cor-relations between wood density or mechanical properties and

growth rate in P deltoides × nigra.

The objective of this study is to evaluate the

variabil-ity in selected physical and mechanical properties of new

inter-American poplar clones (P trichocarpa × deltoides) As

poplar plantations are a local source of wood which take away

pressure from native forests, this also contributes in producing

high value added products with extended service life

2 MATERIALS AND METHODS

A total of 14 trees from three different clones, all P trichocarpa

× deltoides (T×D) hybrids, were felled in a poplar plantation in Lille

(Belgium): six ‘Beaupré’, four ‘Hazendans’ and four ‘Hoogvorst’

The trees had all grown on sandy to loamy sand soils with a poor

drainage, in adjacent stands with a planting distance of 8× 8 m Trees

were selected in respect of their diameter at breast height so that it

was representative of the diameter distribution in the different

clone-site combinations Trees that were suspected to suffer from border

effects, e.g standing near the border of the site or near a dead tree, were excluded The trees were all 21 years old and their circumfer-ence at breast height ranged from 141 to 187 cm Table I gives an overview of genetic background and stand characteristics of the three selected poplar clones

The trees were sawn into stem discs, logs and beams, depending

on the different tests to be performed, according to the scheme shown

in Figure 1 To assess the basic technical quality of each clone, ten-sion wood and (false) heartwood proportion, density, dimenten-sional sta-bility, modulus of elasticity (MOE) and modulus of rupture (MOR) have been quantified at three different heights

For evaluating the amounts of heartwood and tension wood, den-sity and the shrinkage upon drying of the wood, two sets of stem discs were taken at 1.2 m, 6.5 m and 11.5 m (Fig 1) The first set of discs (A) was used to determine amounts of tension wood and heart-wood as well as for the determination of the growth characteristics (tree ring width); the second set (B) was used for sampling test spec-imens to determine wood density and dspec-imensional stability To iden-tify the tension wood zones the surfaces of the cross sections were stained with a zink-chloride-iodine solution The cumulative area of the tension wood zones was then measured digitally and expressed

as a percentage of the cross-sectional area A similar procedure was used for determining the readily visible dark coloured heartwood pro-portion To calculate the amount of heartwood in the whole commer-cial stem, data were volume weighted by extrapolation of the surface measures

In order to evaluate the spatial distribution of the individual tension wood areas, a two-parameter Weibull probability density

function (pdf) was fitted to the data In this case, an evaluation per

clone was made of the likely occurrence of larger tension wood zones

The two-parameter Weibull distribution is described by a shape

fac-torβ and a scale factor α Figure 2 shows the measured frequencies

per class of tension wood proportions, as well as the fitted Weibull

distribution The fits were correlated well with the measured data and

statistical significant (p= 0.01) for all clones

In order to quantify wood density and the dimensional stability

of timber, cubic specimens with 30 mm ribs, were cut out of the

stem discs B according to the major wind directions (Fig 1) The

specimens were first measured in fresh condition and then were

sub-jected to consecutive changes in relative air humidity (RH) in a

cli-mate room at 90% RH over 60% RH to 40% RH, all at 20◦C and

finally to oven-dry state

Density was calculated at different stages of moisture content

These data were used to determine correlations between shrinkage

parameters and densities Density was always expressed at

equilib-rium of a certain conditioning phase (As the mass to the volume at the

specified RH) A weighted average (volume based) of the obtained

densities at 60% RH was compared to the weighted average based on

the samples used for mechanical testing to validate the density

mea-surements The density values later on reported (Tab III and Fig 5)

are density values determined at 60% RH Mass was determined at

an accuracy of 0.001 g while the dimensions were determined using

a calliper with an accuracy of 0.01 mm

For the mechanical tests stem parts of 50 cm in length (M) were

taken at three different heights (0.7 m, 6.6 m and 11.0 m) The

mate-rial was subsampled into test specimens of 50 cm axial length and a

cross section of 2× 2 cm in accordance with EN 408 The specimens

were sawn and subsequently planed parallel to the grain and the

an-nual rings aligned with one side of the cross section Every specimen

received its own co-ordinate, so that the exact position in the stem

remained known The sawn pattern was designed to provide a

max-imal number of flawless test specimens at each height (Fig 1) The

number of test specimens per clone per height level ranges from 10

to 25

The 50× 2 × 2 cm samples were conditioned at 60 ± 2% relative

humidity and 20± 1◦C It took for all samples 5 weeks to reach the

equilibrium state The EMC at 60% RH was 12.7% with a standard

deviation of 0.6% The static edgewise modulus of elasticity (MOE)

and the modulus of rupture (MOR) were determined by means of a

4-point bending test, according to EN 408 The knot-free specimens

were loaded at the centre at a rate of 8 mm per min in order to reach

a duration of the test of 300± 120 s

Of each stem, two logs of 2.6 m were peeled using industrial

equipment to evaluate veneer quality and, subsequently, plywood

properties The thickness of the veneer was 1.5 mm The logs were

exactly measured using laser scanning technology, allowing to

deter-mine the centre points for optimal yield The total amount of veneers

produced allowed a first yield figure Clipping losses related to edge

trimming and defect elimination were also taken into account

Af-ter drying some veneers were rejected due to excessive crack

for-mation or extreme waviness As such, three quality classes were

discerned These quality classes were described by the commercial

grading system of the peeling company Next to the description of

the discerned classes a parallel was made to the five quality classes

used by EN 635-2 The A-quality is referring to closed veneers

(ab-sence of defects) (is comparable with the combined classes E and I of

EN 635-2), whereas B-quality allows small defects (small checks or

holes) to the extent that they can be technically repaired (is

compa-Figure 2 Example of observed histogram of tension wood surface

proportions (classes of 2.5%) and fitted two-parameter Weibull prob-ability density function, for the clone ‘Beaupré’

rable with the combined classes II and III of EN 635-2) C/D-quality veneers contain larger defects and are used for the interior plies of the board only The latter class is comparable to the quality class IV of the EN 635-2 standard

Out of the top quality veneers (A and B classes), seven-layer plywoods were produced using an urea-formaldehyde glue These boards were tested for density, MOE and MOR (in both veneer directions) according to EN 310 Per clone 10 samples (thickness

× 500 × 50 mm) were tested per veneer direction

In the result section, the significance of a statistical analysis is

indicated by a number of asterisks (* p = 0.05; ** p = 0.01; *** p =

0.001)

3 RESULTS 3.1 Dendrometrical measurements

Table I gives an overview of some selected dendrometri-cal features for the investigated clones The radial as well

as the height growth of ‘Hoogvorst’ are significantly (p = 0.05) higher than those of ‘Beaupré’ and ‘Hazendans’ The growth profiles (results not presented) showed that the diame-ter growth culminates earlier for ‘Beaupré and Hoogvorst (8–

10 years) than for ‘Hazendans’ (12–15 years) The mean val-ues given in table I are based on measurements at breast height only Similar trends have been observed, however, higher in the stem

3.2 Heartwood and tension wood proportions

Table II shows the proportions of heartwood and tension wood recorded for the three poplar clones

A Duncan’s multiple range test allowed determining sig-nificant clonal differences (p = 0.05) in average amounts of heartwood This analysis shows that the amount of heartwood

is significantly higher for ‘Hazendans’ (±40%) than for both

Table II Average heartwood and tension wood proportions (%) at three different heights, as well as the volume weighted average with standard deviation and the minimum and maximum values

(a) Heartwood proportion

(b) Tension wood proportions

‘Beaupré’ and ’Hoogvorst’ (±30%) The proportion of

heart-wood decreases linearly with height Highly significant

lin-ear regressions (y = Ax + B) were obtained for all clones

(‘Beaupré’ A = −3.8; B = 52.0; R2 = 0.95**; ‘Hazendans’

A = −2.6; B = 60.0; R2 = 0.83**; ‘Hoogvorst’ A = −3.2;

B = 50.6; R2= 0.93**)

A Duncan multiple range test did not point out differences

between the tension wood proportions (Tab IIb) for the three

clones, all having volume weighted average values around

12% At breast height, higher relative amounts of tension

wood were observed Higher in the stem no trend in tension

wood occurrence could be distinguished

Figure 3 represents for each clone individually the

fit-ted two-parameter Weibull distribution of the surface

propor-tion of individual tension wood zones This graph shows that

‘Hoogvorst’ and ‘Hazendans’ have similar distributions

com-pared to ‘Beaupré’ The distributions cross at a surface

propor-tion of an individual zone of 6.25%

The distribution of ‘Beaupré’ indicates that this clone has a

bigger amount of smaller individual tension wood areas (85%

of the tension wood zones< 6.25%) ‘Hoogvorst’ and

‘Hazen-dans’ (respectively 55% and 54%< 6.25%) have more

ten-sion wood zones of larger surface proportion Therefore, the

occurrence of larger zones is less likely in ‘Beaupré’ than in

‘Hoogvorst’ and ‘Hazendans’, or ‘Beaupré’ has more diffuse

tension wood than ‘Hoogvorst’ and ‘Hazendans’

3.3 Density, mechanical properties and dimensional

stability

Surface weighted densities for each height level as well as

the total volume weighted density for the investigated clones

0 0.1 0.2 0.3 0.4

Surface proportion [%]

Beaupré Hazendans Hoogvorst

Figure 3 Fitted two-parameter Weibull pdf, showing the surface

pro-portion distributions of individual tension wood zones for the inves-tigated clones

are reported in Table III When density is calculated without

a volume based weighing, the average values at the bottom height are 15 to 25 kg/m3lower A similar trend is found for MOE (400 to 800 N/mm2lower) and MOR (5 to 15 N/mm2 lower)

Density increases linearly (y = Ax + B) with height

(‘Beaupré’ A = 10.9; B = 356; R2 = 0.95**; ‘Hazendans’

A = 10.3; B = 394; R2 = 0.96** and ‘Hoogvorst’ A = 6.8;

B = 362; R2 = 0.96**) An analoguous trend as for density was observed in the results of the bending tests (MOR and MOE)

The specific strength (ratio of mechanical property and den-sity) is highest for ‘Beaupré’ when stiffness is concerned, while ‘Hoogvorst’ has the highest ratio in terms of strength This also provides a measure of suitability as construction tim-ber

Table III Surface weighted average values for density, modulus of elasticity and modulus of rupture at three different heights, as well as the volume weighted average, with standard deviation, minimum and maximum values

(a) Density (kg /m 3 )

(b) Modulus of elasticity (N /mm 2 )

(c) Modulus of rupture (N/mm 2

)

A significant correlation (R2 = 0.86*) was found between

the average basic density measured at breast height and the

overall basic density of the total merchantable stem (basic

den-sity of the total merchantable stem=1.11 × density at breast

height), irrespective of the clone

Table IV shows for two different intervals of relative air

hu-midity (RH) the global mean shrinkage in tangential and radial

direction together with the shape factor (tangential shrinkage

divided by radial shrinkage) and the mean volumetric

shrink-age

Stability (low shrinkage values) decreases with increasing

height, following the trend of increasing density

3.4 Veneer quality – Density and mechanical

properties of plywood

Figure 4 gives an overview of the efficiency of the veneer

processing as well as the different yield parameters

‘Hazen-dans’ shows most trim clipping losses in peeling, due to its

less cylindrical stem form In ‘Beaupré’ a substantial lower

amount of veneers is lost in the drying process Table V gives more detailed information on the veneer quality and points out the different reasons for excluding veneer sheets

The overall yield of veneer produced is significantly higher

in ‘Beaupré’ than in the other clones When the produc-tion of quality veneers (white veneers of grade A) is con-sidered, major differences can be pointed out ‘Hazendans’ and ‘Hoogvorst’ have very low yields of grade A veneers

‘Hoogvorst’ shows a significantly lower yield of grade B ve-neers and produces a large amount of grade C/D veneers which are only suitable for the interior of plywood boards All ve-neers of ‘Hazendans’ have a uniform white colour

Only the A/B-quality veneers were used to produce ply-wood resulting in 3 to 5 panels (1 250× 2 500 mm) per clone Table VI gives an overview of the density, modulus of elas-ticity and modulus of rupture for each clone Both mechanical properties were tested perpendicular and parallel to the grain

as described in EN 310 The average strength values of boards made of ‘Hoogvorst’ veneers are significantly lower than those

of ‘Hazendans’ and ‘Beaupré’

Table IV Mean clonal shrinkage values (radial (R), tangential (T) and volumetric) and shape factor for two different intervals of relative air humidity and the multiple range statistics by Duncan

(a) From 90% to 60% relative air humidity (%)

(b) From 60% to 40% relative air humidity (%)

(%) (%) (%) (%)

Figure 4 Volume efficiency and losses during manufacturing of veneers disregarding the end-quality

Table V Assessment of the veneer quality and detailed information on losses and yields.

Veneer quality (%)

Loss of veneer (%)

Table VI Density (kg/m3), modulus of elasticity and modulus of rupture (N/mm2) for a 7-layer plywood for each of the selected clones.

The densification, i.e the density of the raw material versus

the density of the pressed board, is higher for ‘Hazendans’ and

‘Hoogvorst’ (12%) in comparison with ‘Beaupré’ (10%) For

this reason the strength values of the ‘Hazendans’ plywood are

slightly higher than those of ‘Beaupré’ An inverse trend was

shown for the strength properties of the solid wood

4 DISCUSSION

4.1 Influence of growth rate and genetic background

The clone ‘Hoogvorst’ has a radial growth rate that is 20

to 25% higher than ‘Beaupré’ and ‘Hazendans’ (Tab I)

Al-though a trend in decreasing density, modulus of elasticity

and modulus of rupture with an increasing radial growth rate

can be discerned, no significant correlation could be found

between growth features and physical mechanical properties

Hernández [10] and Pliura [19] found a significant but weak

negative correlation between radial increment and density

Several features have an influence on this correlation Firstly,

the data set used here represent only a narrow range, both in

growth rate and density, which is insufficient to detect

signif-icant trends Diffuse porous species, such as poplar, generally

display only a weak response in density to changing growth

rates Finally, the presence of tension wood tends to increase

the local density, irrespectively of growth rate

Zobel and Jett [26] state that for several important wood

characteristics (i.e heartwood formation, density and fibre

length), a genetic control has been demonstrated Klasnja

et al [13] reported a coefficients of heritability of 0.94 for

density and 0.61 for mean fibre length in Populus deltoides

clones The investigated clones are genetically closely

re-lated (‘Beaupré’ and ’Hoogvorst’ have the same mother and

‘Hoogvorst’ and ‘Hazendans’ have the same father) Some

caution remains, however, with respect to conclusion

concern-ing the heritability effect, because the crossing between clones

V471 and S1-173 is missing in the experiment (Tab I) The

latter crossing was rejected earlier in the selection stage due

to lower disease resistance and eccentric stem form Some of

the variations in wood properties, have nevertheless, been

in-terpreted in terms of parental background

In relative terms, the clone ‘Hazendans’ produces 30%

more heartwood than ‘Hoogvorst’ and ‘Beaupré’ This

in-dicates a positive genetic influence of the mother clone in

‘Beaupré’ and ‘Hoogvorst’ in lowering the heartwood

propor-tion

Although the mean values for tension wood proportions presented in table II are not discerned by a Duncan range test, the distribution of surface proportion of individual ten-sion wood zones differs for ‘Beaupré’ in comparison to the other clones As has been shown in Figure 4, ‘Hoogvorst’ and

‘Hazendans’ present a more aggregated presence of tension wood This might be attributed to an influence of their mutual father clone

Density is a very strong inheritable feature [13, 26] How-ever, the Duncan multiple range test groups the genetically most different clones (‘Beaupré’ and ‘Hazendans’) in our study (Tab III) It seems likely, therefore, that the interclonal

differences in density are determined mainly by differences in growth dynamics The lower density of the clone ‘Hoogvorst’ can indeed be explained by its more rapid growth since this may produce thinner cell wall structures Thus, at the same growth rate, all three clones are expected to yield similar den-sity values These results differ from the findings of Zhang

et al [25], who reported that clonal effects on wood density were stronger than growth trait effects However, this conclu-sion was based on very young trees (3-year-old material) Concerning shrinkage behaviour, contrasting conclusions could be drawn respectively for the ranges of interior and exterior applications Under low relative air humidity condi-tions, wood from ‘Beaupré’ and ’Hoogvorst’, which have the same mother, behaves similarly (Tab IVb) Conversely, under higher relative air humidity conditions, wood from ‘Hazen-dans’ and ‘Hoogvorst’ (same father) displays similar dimen-sional stability (Tab IVa) This apparent switch in parental in-fluence may be due to genetically determined differences in the chemical composition and the moisture sorption behaviour

of the wood cell walls

According to Zobel and Jett [26], it is possible to ge-netically select poplars for a lower degree of heartwood discoloration The mother clone of ‘Beaupré’ and ‘Hoogvorst’ appears to have a negative influence on the whiteness of the veneer sheets The influence is lower in ‘Beaupré’ than in

‘Hoogvorst’ (Tab V)

4.2 Relationships between tension wood proportion, heartwood and physical-mechanical properties

An important feature in the industrial processing of poplar wood remains the occurrence of tension wood fibres and their distribution within the stem volume The formation

of tension wood is induced by a gravitational stimulus [5]

This was experimentally proven by Jourez et al [11] for

P-euramericana cv ‘Ghoy’ Badia et al [1, 2] reported

dif-ferent patterns of tension wood distribution between clones

They also stated that tension wood extent is highest at the tree

base, which is also reflected in the data presented in Table II

The variation in the amount of tension wood fibres can vary

as much as 22% to 63% [7, 17] In terms of spatial

distribu-tion, tension wood occurrence is more diffuse in ‘Beaupré’

(Fig [3]) than it is in the other two clones, resulting in

flat-ter drying of the veneer sheets, i.e a lesser degree of waviness

(Tab V)

‘Beaupré’ and ‘Hazendans’ have a relatively higher

lin-early increase of density with height (respectively± 11 and

± 9 kg/m3) than ‘Hoogvorst’ (± 7 kg/m3) (Tab III) This is

explained by the fact that the heartwood proportions (Tab II)

as well as the ratio of heartwood to sapwood density differ for

each clone For ‘Beaupré’ this mean ratio is 0.94 meaning that

heartwood density is lower than sapwood density In

combina-tion with a rapid decrease of heartwood proporcombina-tion with height

(Tab II), this results in a more rapid increase of density with

height For ‘Hoogvorst’ and ‘Hazendans’, the mean ratios are

respectively 1.05 and 1.02, meaning that heartwood is slightly

denser than sapwood For the clone ‘Hazendans’, this density

ratio combined with its high amount of heartwood results in a

comparatively fast increasing density with height Due to the

lower heartwood proportion and the slower decrease of

heart-wood proportion with height in ’Hoogvorst’, the increase in

density is less pronounced

The relation between density and mechanical properties

(MOE and MOR) at different heights is graphically

repre-sented in Figure 5

The modulus of elasticity is strongly (p= 0.05) positively

correlated with density This trend is significant at the clonal

level as well as at the interclonal level The modulus of rupture

increases also with increasing density, but this holds only at the

clone level

At the interclonal level, density does not allow to explain

variation in MOR In fact, ‘Hoogvorst’ which has the

low-est density (Tab IIIa), exhibits the highlow-est mean values for

MOR (Tab IIIc) Moreover, ‘Hoogvorst’ has the highest ratio

(MOR/density) i.e 0.19 (0.16 for ‘Hazendans’ and 0.15 for

‘Beaupré’) This implies the existence of a additional

influenc-ing factor Different authors described the clonal influence on

fibre length [4, 9, 16] Fibre length does not have a significant

or consistent influence on density [8], but will likely affect the

maximal load capacity (i.e MOR)

At every moisture content, density is significantly (p =

0.05) correlated with the volumetric shrinkage for the interval

of 60% to 40% RH For other intervals no significant

correla-tions could be found

The overall shrinkage values are clearly lower in

compari-son to earlier reported data [14, 15] for other clones, allowing

to conclude that the wood of these inter-American clones is

more stable A more profound classification of wood of these

clones should be made with regard to their possible end-use

In fact, the evaluation of dimensional stability is depending

on the application corresponding with a specific range in RH

Differences in absolute volumetric shrinkage between clones

lie within 0.5 to 1.0% for exterior applications (90–60% RH) and interior applications (60–40% RH), but the differences in shape factor are more important Based on that shape factor,

‘Beaupré’ seems the best clone, both for interior and exterior applications (Tab IV) Basing on these results, ‘Hazendans’ seems to be the least suited for interior applications, while

‘Hoogvorst’ is the least suited for exterior use

The positive correlations between density and volumetric shrinkage between 60% and 40% RH allow to rank poplar clones for their suitability for interior applications, since wood density can be determined relatively easy and fast On the other hand, for outdoor applications the specific shrinkage or swelling values have to be determined

4.3 Potential of veneer based products

Compared to the traditional ones, all tested clones show an acceptable net efficiency in veneer peeling, although the losses are distributed differently due to several causes (Tab V) All clones have high clipping losses due to holes (unac-ceptable big knots or loose knots) This can be reduced sig-nificantly by an adapted tree management, including pruning

at early age The losses due to crack formation after peeling are higher in ‘Beaupré’ This is due to the release of internal growth stresses which can not be solved by tree management nor production parameters Higher internal tensions also may explain the relatively high losses due to cracks formed during drying (40% of the total drying losses) The clonal differences

in veneer losses due to drying defects narrows the potential use of poplar clone mixtures as one source of raw material in veneer products An adaptation of the drying process may par-tially prevent such losses

The spatially more diffuse tension wood in ‘Beaupré’ (Fig 3) explains the lower amount of waviness after drying, when compared to the other clones The smaller range in den-sity values of this clone (Tab III), also contributes to this ef-fect

White colour of poplar veneer sheets is important in es-thetical applications Therefore, the darkening and striping of wood caused by heartwood discoloration, depreciates veneer quality [6, 23] This type of wood is less suitable for furni-ture production, visible structural applications or applications where a printable surface is required (packaging material and fruit boxes) Overall, only ‘Beaupré’ and ‘Hazendans’ pro-duce an acceptable amount of white veneers, i.e around 20% White veneer yield may be enhanced by pruning, especially in

‘Beaupré’, but this will result only in a minor improvement in

‘Hazendans’ and ‘Hoogvorst’ due to their un favourable heart-wood proportion and distribution

For all clones, the board properties reported in Table VI are well within range to produce plywood for structural appli-cations Variations in plywood properties are expected to be lower when mixtures of veneers (different clones and/or qual-ities) are used in the production process (with a accurate grad-ing of the mixed veneers and correspondgrad-ing layered structure

of the plywood)

(a) (b)

5000

6000

7000

8000

9000

10000

Density (kg/m³)

0 25 50 75 100 125

5000 6000 7000 8000 9000 10000

Density (kg/m³)

0 25 50 75 100 125

5000

6000

7000

8000

9000

10000

Density (kg/m³)

0 25 50 75 100 125

5000 6000 7000 8000 9000 10000

Density (kg/m³)

0 25 50 75 100 125

MOE Beaupré MOE Hazendans MOE Hoogvorst MOR Beaupré MOR Hazendans MOR Hoogvorst

Figure 5 Relation between density and Modulus of elasticity (MOE) and Modulus of rupture (MOR) for the investigated clones at three

different heights (breast height (a); at 6.5 m (b); at 11.5 m (c)) and their volume weighted averages for the whole stem up to 11.5 m (d)

4.4 Main conclusions

It can be concluded that ‘Beaupré’ is suitable for both

ply-wood and sawn ply-wood production ‘Hazendans’ has good

av-erage characteristics supporting its use in sawn wood based

products Its yield of white veneers is sufficient for the

pro-duction of plywood in esthetical applications The clone

‘Hoogvorst’ produces too few white veneers, restricting the

use of its veneers to structural plywood manufacturing The

larger values found for the shape factor in this clone may limit

its use in sawn wood based products

Further research on clonal variation in properties is needed

to assess adequate processing strategies for multiclonal poplar

stands (extending the number of sampled trees and the number

of stands)

Acknowledgements: This study has been financed by the Institute

of Nature and Forest Research (INBO – Geraardsbergen, Belgium)

of the Ministry of the Flemish Community within the framework of

the project “Tree and wood Quality Research for the Flemish

Forest-Wood Chain”

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